JP6579776B2 - Fire alarm equipment and fire detector - Google Patents

Description

  The present invention relates to a fire alarm facility and a fire detector for testing a fire detector of a fire detector.

  As a conventional fire alarm system, one of the multiple fire detectors connected to the fire receiver is made to function as a parent fire detector by the test setting switch, and the remaining fire detectors are switched to the test setting. The tester outputs a test signal that causes the fire detector (infrared sensor) to be tested including the self from the parent fire detector, and multiple child fire detectors receive the fire in order. Some perform part tests. The test signal is configured to be output once a day by a timer of the parent fire detector (see, for example, Patent Document 1).

JP 2007-148562 A

  By the way, each fire detector has a built-in timer, and there are some which perform an operation test of the infrared sensor at different timings by using the timer. As timers used in fire detectors (including the timer of Patent Document 1), for example, many timers measure the time by the number of times of charging / discharging of the CR circuit. When used for a long time, the timer of the fire detector is used. An error may occur in the measurement time. In addition, when the fire detector is replaced due to a failure or the like, the timing of the test may overlap due to the effect of timing shift of power-on due to replacement work. In such a situation, a large current flows during the test and the power supply capacity is exceeded, or the power supply voltage of the fire detector fluctuates greatly due to a voltage drop due to wiring resistance, so that the fire detector function can be maintained. It may disappear.

  The present invention has been made in order to solve the above-described problems. It is possible to test fire detectors one by one in order to prevent overlapping of the test timings of the fire detectors. To provide a fire alarm system and a fire detector capable of preventing the overlap of fire detector test timing due to a timing shift of power-on when a fire detector is replaced even if the test is performed in sequence one by one. For the purpose.

In the fire alarm facility according to the present invention, a plurality of fire detectors with a test function are connected to a transmission line from a fire receiver, and the fire receiver transmits a test result return command to each fire detector via the transmission line. and, wherein each fire detector, as a response to the test result return command, the fire alarm system transmits the test result signal to the fires receiver via the transmission line, the fire detector, each fire Address storage means for storing its own address uniquely set by the sensor, and reception for receiving a test result return command from the fire receiver or a test result signal from another fire sensor via a transmission line and means, the test execution means for executing a test of the fire detector, wherein the test executing means, wherein the test result signal transmitted from the fire detector that owns one previous address than own address Receiving means Then, when the receiving means receives the test result return command transmitted to the fire detector having the address one before the own address, it executes the test of its own fire detection unit, and Even if the first predetermined time elapses after the receiving means receives the test result signal transmitted from the fire detector having the address two addresses before the address, it is one previous from its own address. If the receiving means does not receive the test result signal transmitted from the fire detector that owns the address, the fire detection unit executes the test of its own fire, or the fire owns the address one before its own address Even if the third predetermined time has elapsed since the receiving means received the test result return command transmitted to the sensor, the test is transmitted from the fire sensor that owns the previous address before its own address. The Test results When the signal the receiving means does not receive that, so that to perform a test of the self-fire detector.

  According to the present invention, when the receiving means receives a test result signal transmitted from a fire detector that performs a test before one of the fire detectors connected to the transmission line, or When the test result return command sent to the fire detector that executes the test one time before the self is received, the test of the fire detector of its own is executed. Overlap can be prevented. In particular, the test timing of each fire detector does not overlap with other fire detectors, compared to a fire detector that takes a test timing with its own timer. For this reason, the power supply capacity does not exceed at the time of the test, and the power supply voltage of the fire detector due to the voltage drop of the transmission line does not fluctuate greatly, so that the function deterioration of the fire detector can be suppressed.

The block diagram which shows schematic structure of the fire alarm equipment which concerns on embodiment of this invention. The block diagram which shows schematic structure of the fire receiver of FIG. The block diagram which shows schematic structure of the fire detector of FIG.

Hereinafter, embodiments of the fire alarm system and the fire detector according to the present invention will be described with reference to the drawings.
1 is a block diagram showing a schematic configuration of a fire alarm facility according to an embodiment of the present invention, FIG. 2 is a block diagram showing a schematic configuration of a fire receiver in FIG. 1, and FIG. 3 is a schematic diagram of the fire detector in FIG. It is a block diagram which shows a structure.
As shown in FIG. 1, the fire alarm facility according to the present embodiment includes a fire receiver 10 and a plurality of fire detectors 20 (with a test function) connected to transmission lines L1 and L2 from the fire receiver 10, respectively. An example of a fire detector). For example, 255 fire detectors 20 that can be connected to one line as a group 1 are connected to the transmission line L1, and 150 fire detectors 20 as a group 2 are connected to the transmission line L2. . The number of groups and the number of fire detectors 20 for each group are examples and are not limited.

  As shown in FIG. 2, the fire receiver 10 includes a control unit 11, various switches (not shown) such as a recovery switch and an alarm sound stop switch provided for each group, and a display including an LCD constituting a display device. An operation unit 12, a storage unit 13, and a transmission / reception unit 14 to which a plurality of fire detectors 20 are connected via transmission lines L1 and L2, respectively.

  The control unit 11 repeatedly transmits, for example, a state collection command for confirming the operation state of each fire detector 20 alternately to each fire detector 20 for each group (each transmission line L1, L2) at a constant cycle. To do. When the state response signal is received from each fire detector 20 via the transmission lines L1 and L2 by transmitting the state collection command, the control unit 11 fires with a state change (failure or the like) based on the state response signal. The sensor 20 is specified. In addition, when the fire detector 20 having a state change is specified, the control unit 11 stores the group number, address, installation location, state change information, and the like of the specified fire detector 20 in the storage unit 13 in association with each other. In addition, they are displayed on the LCD of the display operation unit 12 for notification. Further, when the state response signal is not received, the control unit 11 determines that the state is abnormal (no response), and stores the group number, address, installation location, and the like of the fire detector 20 that does not have the state response signal in association with each other. They are stored in the unit 13 and displayed on the LCD of the display operation unit 12 for notification.

Here, the fire receiver 10 includes, as the storage unit 13, an address storage unit that stores the address of the fire detector 20 connected to each of the transmission lines L1 and L2. Then, the fire receiver 10 refers to the address storage unit, and transmits, as a state collection command, the address of the fire detector 20 for each transmission line L1, L2, and transmits the designated address. Only one or a plurality of fire detectors 20 are caused to respond and a state response signal is transmitted. And by sending such a state collection command cyclically to all the fire detectors 20, the fire receiver 10 receives state responses from all the fire detectors 20 connected to the transmission lines L1 and L2. The signal can be received.
In addition, the fire receiver 10 includes a test order storage unit that stores the test order of the fire detectors 20 connected to the transmission lines L1 and L2 as the storage unit 13. The test order storage unit stores the order of tests corresponding to the addresses of the fire detectors 20 for each of the transmission lines L1 and L2. In this embodiment, the test order of the fire detectors 20 at the addresses “001”, “002”,... “255” is “001”, “002”,. That is, for each transmission line L1, L2, the address of each fire detector 20 is stored as it is in the test order.
And the fire receiver 10 uses this test order storage part periodically, for every period longer than the period for 1 cycle in which all the fire detectors 20 transmit a state response signal, for example, every week, regularly A test result return command is transmitted to each fire detector 20 and a test result signal is received as a response.

For example, taking the transmission line L1 as an example, the fire receiver 10 refers to the test order storage unit and first designates the address “001” of the first fire detector 20 and transmits a test result return command. The test result signal is transmitted by responding only to the designated fire detector 20 with the address. Then, the test result return command is sent to all the transmission lines L1 in the order of the address “002” of the second fire detector 20 and the address “225” of the last fire detector 20. The fire receiver 10 is configured to be able to receive test result signals from all the fire detectors 20 connected to the transmission line L1 by cyclically transmitting the fire detector 20 to the fire detector 20. .
When the test result signal is received from each fire detector 20 via the transmission lines L1 and L2 by the transmission of the test result return command, the control unit 11 of the fire receiver 10 fires based on the test result signal. The test result (test normal or test abnormal) of the sensor 20 is specified. In addition, when the control unit 11 specifies the test abnormality fire detector 20, the control unit 11 stores the group number, address, installation location, state change information, and the like of the specified fire detector 20 in the storage unit 13 in association with each other. In addition, they are displayed on the LCD of the display operation unit 12 for notification.

  The transmission cycle of the test result return command is set to 10 seconds, for example, and the fire receiver 10 transmits the test result return command to the Nth fire detector 20 and then the N + 1th fire. If the test result signal is not received from the Nth fire sensor 20 until the test result return command is transmitted to the sensor 20 (10 seconds), the Nth fire sensor 20 is abnormal (no response). ), The group number, address, installation location, and the like of the fire detector 20 determined to be abnormal are associated with each other and stored in the storage unit 13 and displayed on the LCD of the display operation unit 12 for notification.

As shown in FIG. 3, each fire detector 20 is a flame detector including an infrared sensor 23 made of, for example, a pyroelectric element, and includes a control unit 21, an infrared sensor 23 that is a fire detection unit, and an infrared sensor. 23 includes a test light source 22 that emits pseudo fire light when performing a test of the light receiving sensitivity 23, a storage unit 24, a transmission / reception unit 25, and a timer 26. The aforementioned infrared sensor 23 receives the infrared rays of the CO ₂ resonance radiation radiated from the flame, converts them into electrical signals according to the received light amount, and inputs them into the control unit 21. The storage unit 24 stores its own address set uniquely for each fire detector 20.

  For example, as shown in FIG. 1, the address set for each fire detector 20 is a serial number assigned to each group, and “001” is assigned to the fire detector 20 closest to the fire receiver 10. The numbers “002” and “003” are assigned in order as the distance from the fire receiver 10 increases. The last fire detector 20 in group 1 is assigned an address “255”, and the last fire detector 20 in group 2 is assigned an address “150”.

  The transmitter / receiver 25 receives a status collection command and a test result return command transmitted from the fire receiver 10 via the transmission line L1 (or L2) at a constant cycle, and other fire detectors will be described later. 20 has a receiving means for receiving the test result signal from 20 via the transmission line L1 (or L2).

The control unit 21 of each fire sensor 20 is transmitted from the fire sensor 20 that executes the test one before the self among the fire sensors 20 connected to the transmission line L1 (or L2). When the test result signal is received by the transmission / reception unit 25, the test light source 22 is made to emit light, and the test execution means for executing the test of the infrared sensor 23 is provided.
Here, in the present embodiment, as described above, each fire detector 20 tests the fire detector 20 for each transmission line L1, L2 in order from the smallest address of each fire detector 20. Execute. Therefore, when the test result signal transmitted from the fire detector 20 having the address one before the own address is received by the transmission / reception unit 25, the control unit 21 turns the test light source 22 on as described above. The infrared sensor 23 is tested by emitting light, and the test result is stored in the storage unit 24. And when the test result return command transmitted from the fire receiver 10 is received, the test result signal to which the test result information is attached is transmitted to the fire receiver 10 (and other fire detectors 20). The test result signal includes a group number and its own address.

  In addition, the control unit 21 passes the first predetermined time after the transmission / reception unit 25 receives the test result signal transmitted from the fire detector 20 that owns the address two prior to its own address. When the transmission / reception unit 25 does not receive the test result signal transmitted from the fire detector 20 having the address immediately before its own address, the test light source 22 is caused to emit light and the test of the infrared sensor 23 is executed. That is, it is abnormal (no response) such as the fire detector 20 having the previous address being removed from the transmission line L1 (or L2) by replacement, and the operation test cannot be performed. Judgment is performed, the order of the tests is skipped, the test is executed, and the test result is stored in the storage unit 24. As described above, when a test result return command transmitted from the fire receiver 10 is received as a test result signal to which the test result information is attached, the fire receiver 10 (and other fire detectors 20). Send to.

Whether the address is the previous address and whether the previous address is the address (number) included in the test result signal transmitted from the fire detector 20 that owns the address, and its own address (number). Are compared. That is, the control unit 21 of each fire detector 20 on the same transmission line L1, L2 determines its own test timing from the test result signal transmitted from the other fire detector 20 that has been tested, It is determined from the timer 26 whether or not the first predetermined time has elapsed since the reception of the test result signal transmitted from the fire detector 20 having the address two before the previous address.
Here, as described above, since the transmission cycle of the test result return command in the fire receiver 10 is set to 10 seconds, for example, the transmission cycle of the test result signal based on the test result return command is also about 10 seconds. Become. Therefore, the first predetermined time may be a time slightly longer than 10 seconds, but in the present embodiment, the first predetermined time is set to, for example, 13 seconds in consideration of the transmission error of the test result signal. Is set.

The control unit 21 of the fire detector 20 having the smallest address (001) on the same transmission line L1, L2, that is, the fire detector 20 that first performs an operation test on the same transmission line L1, L2. When the second predetermined time longer than the cycle of one cycle in which all the fire detectors 20 execute the test has elapsed after executing the self test, the control unit 21 newly starts the infrared sensor 23 of its own. The test is executed and the test result is stored in the storage unit 24. Thereby, it can prevent that another fire detector 20 and a test timing overlap.
The second predetermined time is longer than the time from the first fire detector 20 to the 255th fire detector 20 ending the test among 255 fire detectors 20 that can be connected to one line. It's time. The number of fire detectors 20 on the group 2 is 150. When the second predetermined time has elapsed, a test of the own infrared sensor 23 is newly executed. The second predetermined time may be set according to the number of fire detectors 20 connected for each group.
Here, as described above, since the transmission cycle of the test result signal based on the test result return command is about 10 seconds, the time required for 255 fire detectors 20 connectable to one line to finish the test is as follows. 2550 seconds which is 255 times 10 seconds. Therefore, the second predetermined time may be a time longer than 2550 seconds. In the present embodiment, the second predetermined time is longer than 2550 seconds and shorter than the transmission period (for example, one week) of the test result return command to the fire detector 20 by the fire receiver 10. For example, it is set to one day.
Note that the control unit 21 of the fire detector 20 that first performs an operation test on the same transmission line L1, L2 is turned on as a second predetermined time when the power is turned on when no test has been performed. The elapsed time is measured, and when the second predetermined time has elapsed, the test of the infrared sensor 23 of itself is executed.

In the fire alarm system configured as described above, the operation when a fire occurs will be described.
When a flame is generated by a fire, the infrared sensor of the fire detector 20 installed at the place receives infrared rays generated from the flame, converts them into electrical signals according to the amount of received infrared rays, and inputs them to the control unit 21. The control unit 21 compares the voltage value (or current value) of the input electrical signal with a preset fire determination value. When the voltage value of the electrical signal is greater than or equal to the fire determination value, the control unit 21 generates a fire detection signal including the group number and its own address and stores the fire detection signal in the storage unit 24.

On the other hand, for example, the control unit 11 of the fire receiver 10 transmits a state collection command to each fire detector 20 of the group 1 (transmission line L1), and then each fire detection of the group 2 (transmission line L2). A state collection command is transmitted to the device 20, and this is alternately and repeatedly transmitted at a constant period.
When the control unit 21 of each of the fire detectors 20 in group 1 and group 2 receives a status collection command addressed to its own address, the control unit 21 refers to the storage unit 24, and if a fire is detected, A fire detection signal is transmitted from the transmission / reception unit 25 to the fire receiver 10 via the transmission line L1 (or L2). When no fire is detected, a normal signal is transmitted as a state response signal.
When a fire detection signal is input to the transmission / reception unit 14 of the fire receiver 10, the control unit 11 causes the group number included in the fire detection signal, the address of the fire detector 20, the installation location of the fire detector 20, and the occurrence of a fire. Is stored in the storage unit 13 and the information is displayed on the LCD of the display operation unit 12, and a buzzer built in the fire receiver 10 is activated to generate an alarm sound and notify the administrator. To do.

Next, the test operation of the fire detector 20 will be described.
First, after installing all the fire detectors 20 on the transmission lines L1 and L2 (groups 1 and 2), the fire receiver 10 is turned on to turn on the fire detectors 20. . Then, as described above, the control unit 11 of the fire receiver 10 periodically transmits a test result return command to each fire detector 20 every week. First, the control unit 11 of the fire receiver 10 refers to the test order storage unit and first designates the address “001” of the first fire detector 20 for the transmission line L1 and issues a test result return command. The test result signal is transmitted by responding only to the designated fire detector 20 with the address. Then, the test result return command is sent to all the transmission lines L1 in the order of the address “002” of the second fire detector 20 and the address “225” of the last fire detector 20. Are sent cyclically to the fire detector 20. Thereafter, a test result return command is similarly transmitted to all the fire detectors 20 for the transmission line L2.

In each fire detector 20 of group 1, the control unit 21 of the fire detector 20 that owns the address (001) measures the elapsed time from power-on, and when the second predetermined time has elapsed, the test light source 22 is turned on. Light is emitted (simulated fire light) and received by the infrared sensor 23, and a test result (test normal or test abnormality) based on the amount of received light is stored in the storage unit 24. The test result stored in the storage unit 24 is overwritten and updated with the latest test result every time the test is performed.
The test result based on the amount of received light is a result based on the determination whether the voltage value (or current value) corresponding to the amount of received light is equal to or greater than the above-described fire determination value. That is, it is determined to be normal when the voltage value corresponding to the amount of received light is equal to or greater than the fire determination value, and is determined to be abnormal when the voltage value corresponding to the amount of received light is less than the fire determination value. The determination value used in the test is not limited to the fire determination value, but may be other determination values for testing.
When a test result return command addressed to the self address transmitted from the fire receiver 10 is received, a test result signal attached with information on the test result stored in the storage unit 24 is transmitted on the transmission line L1. This test result signal is received by the fire receiver 10 via the transmission line L1, and is also received by another fire detector 20 on the transmission line L1.

  On the other hand, the control units 21 of the other fire detectors 20 determine whether or not a test result signal is transmitted from the fire detector 20 that owns the address immediately before its own address, and 2 It is determined whether or not a test result signal is transmitted from the fire detector 20 having the previous address. At this time, when the control unit 21 of the fire detector 20 that owns the address (002) recognizes that the test result signal is transmitted from the fire detector 20 that owns the previous address (001), the test light source 22 Is emitted and received by the infrared sensor 23, and a test result based on the amount of received light is stored in the storage unit 24. When a test result return command addressed to the self address transmitted from the fire receiver 10 is received, a test result signal attached with information on the test result stored in the storage unit 24 is transmitted on the transmission line L1.

  In this way, each time the test result signal is transmitted on the transmission line L1, the infrared sensor 23 in order from the fire sensor 20 having the address “+1” as the address of the fire sensor 20 that transmitted the test result signal. We will conduct the test. Then, the control unit 21 of the fire detector 20 having the smallest address (001) on the group 1 determines whether or not a second predetermined time has elapsed since the execution of the self test. When a second predetermined time longer than the cycle of one cycle in which all the fire detectors 20 execute the test has elapsed, the test of the own infrared sensor 23 is newly executed and the test result is stored in the storage unit 24. Remember. When a test result return command addressed to the self address transmitted from the fire receiver 10 is received, a test result signal is transmitted on the transmission line L1.

  In addition, during the test, the control unit 21 of any one of the fire detectors 20 receives the test result signal transmitted from the fire detector 20 having the address two prior to its own address. If the transmitter / receiver 25 does not receive the test result signal transmitted from the fire detector 20 that owns the previous address after the first predetermined time, the own test light source The infrared sensor 23 is tested by emitting light 22. In such a case, the test is not interrupted in a state where the fire sensor 20 to be tested one before the fire sensor 20 is removed for replacement.

  On the other hand, each fire detector 20 of group 2 performs the test in the order of addresses as in group 1, and when the fire detector 20 having the address “150” finishes the test, it is the smallest on group 2. The control unit 21 of the fire detector 20 that owns the address (001) determines whether or not the second predetermined time has elapsed since the execution of its own test, and when the second predetermined time has elapsed. Then, the test of the own infrared sensor 23 is newly executed, and the test result is stored in the storage unit 24. When a test result return command addressed to the self address transmitted from the fire receiver 10 is received, a test result signal is transmitted on the transmission line L2.

  As described above, according to the embodiment, every time the test result signal is transmitted on the transmission line L1 (or L2), the address of the fire detector 20 that has transmitted the test result signal has the address “+1”. Since the test of the infrared sensor 23 is performed in order from the fire detector 20 to be performed, the test timing of each fire detector 20 is different from that of other fire detectors compared to the fire detector that takes the test timing with its own timer. There is no overlap with the vessel 20. For this reason, the power supply capacity does not exceed at the time of the test (when the test light source 22 emits light), and the power supply voltage of the fire detector 20 due to the voltage drop of the transmission lines L1 and L2 is not greatly changed. Therefore, it is possible to suppress the deterioration of the function of the fire detector 20.

  In addition, after receiving the test result signal transmitted from the fire detector 20 that owns the address two previous to its own address, even if the first predetermined time elapses, it is one prior to its own address. When the test result signal transmitted from the fire detector 20 having the address is not received, the self-infrared sensor 23 is tested. Thereby, even if it is in the state where the fire sensor 20 which should be tested before the own fire sensor 20 is removed, the test can be continuously performed without interruption.

(Modification 1)
In the present embodiment, the tests of the fire detector 20 are performed in the order of the addresses. However, the fire detector 20 stores the address of the fire detector 20 that executes the test one before the self, After the fire detector 20 executes the test, the fire detector 20 may be tested. That is, the fire detector 20 test may not be executed in the order of addresses.

  Each of the fire detectors 20 in the modified example 1 is the fire detector 20 connected to the transmission line L1 (or L2). ) Is stored in the storage unit 24 (an example of the previous address storage unit) and the test result signal transmitted from the fire detector 20 having the address stored in the storage unit 24 is received by the transmission / reception unit 25. And a control unit 21 having test execution means for executing the test of the infrared sensor 23.

  For example, the fire detector 20 that performs the test first on the same transmission lines L1 and L2 is the same as the fire detector 20 that has the smallest address (001) on the same transmission lines L1 and L2 in the present embodiment. When the power is turned on, the control unit 21 of the fire detector 20 measures an elapsed time since the power is turned on, and when the second predetermined time has elapsed, as described above, the test of the own infrared sensor 23 is performed. And the test result is stored in the storage unit 24. When the test result return command addressed to the self address transmitted from the fire receiver 10 is received, the test result signal attached with the test result information stored in the storage unit 24 is transmitted to the transmission line L1 (or L2). To the fire receiver 10 to notify the test result, and cause the other fire detector 20 on the transmission line L1 (or L2) to receive it.

  On the other hand, when the test result signal is received, the control unit 21 of the other fire detector 20 determines whether the address attached to the test result signal is the same as the address stored in the storage unit 24. Among the other fire detectors 20, the control unit 21 of one fire detector 20 to be tested next determines that the address is the same as the address stored in the storage unit 24. The infrared sensor 23 is tested, and the test result is stored in the storage unit 24. When the test result return command addressed to the self address transmitted from the fire receiver 10 is received, the test result signal attached with the test result information stored in the storage unit 24 is transmitted to the transmission line L1 (or L2). To the fire receiver 10 to notify the test result, and cause the other fire detector 20 on the transmission line L1 (or L2) to receive it.

  As described above, when each fire detector 20 receives the test result signal transmitted from the fire detector 20 having the address for executing the test immediately before the self stored in the storage unit 24. Since the test of the own infrared sensor 23 is executed, it is not necessary to make the addresses of the fire detectors 20 serial numbers, and the installation work of the fire detectors 20 becomes easy. In addition, the test timing of each fire detector 20 does not overlap with other fire detectors 20 as compared with the fire detector that takes the test timing with its own timer. For this reason, the power supply capacity does not exceed at the time of the test (when the test light source 22 emits light), and the power supply voltage of the fire detector 20 due to the voltage drop of the transmission lines L1 and L2 is not greatly changed. Therefore, it is possible to suppress the deterioration of the function of the fire detector 20.

(Modification 2)
In the first modification, the address of the fire detector 20 that executes the test one time before the self is stored, and after the fire detector 20 transmits the test result signal, the test of the fire detector 20 is executed. However, in the second modification, before the test is executed, the fire detectors 20 connected to the transmission lines L1 and L2 are referred to the order in which the tests are executed, and one before the self. The address of the fire detector 20 that executes the test is determined.

  Each of the fire detectors 20 in the modified example 2 is the address (previous address) of the fire detector 20 that executes the test one before the self among the fire detectors 20 connected to the transmission line L1 (or L2). Address) and the storage unit 24 (an example of the previous address storage means and the test order storage means) in which the order of executing the tests of the fire detectors 20 on the same transmission lines L1 and L2 is stored, and the fire receiver 10 When the transmission / reception unit 25 receives the state response signal transmitted in response to the state collection command from the communication unit 25, the installation state of each fire detector 20 connected to the transmission line L1 (or L2) is grasped, and the storage unit 24, the address of the fire detector 20 that executes the test one before the self is recognized, and the recognized address and the fire detector 20 stored in the storage unit 24 are referred to. Different from the address Sometimes, an address recognized, and a control unit 21 having an address updating means for updating the address of the fire detector 20 to perform a test on one before the self.

First, the control unit 21 of each fire detector 20 on the transmission line L1 (or L2) transmits a state response signal from another fire detector 20 transmitted in response to a state collection command from the fire receiver 10, respectively. And the installation state of each fire detector 20 connected to the transmission line L1 (or L2) is grasped. For example, it is ascertained how many fire detectors 20 are present before and after the self. Each control unit 21 refers to the order of the tests stored in the storage unit 24, recognizes the address of the fire detector 20 that executes the test immediately before itself, and When the address of the fire detector 20 that executes the test one time before the self stored in advance in the storage unit 24 is different from the address of the fire detector 20 that executes the test one time before the self Update as 20 addresses.
That is, the other fire detectors 20 that cannot receive the state response signal are abnormal (no response) such as being removed from the transmission line L1 (or L2) due to replacement, and the operation test cannot be performed. it is conceivable that. Therefore, each control unit 21 refers to the test order stored in the storage unit 24, and among the addresses of the fire detector 20 that has received the state response signal, the test order is one order before the self-address. The address of the fire detector 20 is determined, and the address is set as the address of the fire detector 20 that executes the test one before the self.
As in the first modification, when the test result signal is received, the control unit 21 of the fire detector 20 receives the address attached to the test result signal one time before the self stored in the storage unit 24. Whether the address is the same as the address of the fire detector 20 that executes the test is determined. If it is determined that the address is the same, the test of the infrared sensor 23 is performed.

  As described above, when the test of each fire detector 20 is executed, the control unit 21 of each fire sensor 20 refers to the order of the test stored in the storage unit 24 and is one before the self. It is determined whether the address of the fire detector 20 that executes the test is the same as the address of the fire detector 20 that executes the test one before the self stored in the storage unit 24 in advance. When both addresses are the same, the control unit 21 of each fire detector 20 measures its own test timing from the address of the fire detector 20 that executes the previous test stored in its own storage unit 24. When the addresses are not the same, the address recognized with reference to the test order is updated as the address of the fire detector 20 that executes the test immediately before itself.

Thereby, in addition to the effect of the modification 1, even if the fire detector 20 to be tested one before the own fire detector 20 is removed, the test is continued without interruption. It can be carried out.
In the second modification, the storage unit 24 stores the address (previous address) of the fire detector 20 that executes the test immediately before itself, and each fire detector 20 on the same transmission line L1, L2. However, only the order in which the tests of the fire detectors 20 are executed on the same transmission line L1, L2 may be stored. It is possible to determine (update) the address of the fire detector 20 that executes the test one before the self, and more specifically, the order of executing the test of each fire detector 20 on the same transmission line L1, L2. Can be updated.

(Modification 3)
In the second modification, depending on whether or not the state response signal transmitted from each of the fire detectors 20 connected to the transmission lines L1 and L2 has been received, the test of the fire detector 20 that executes a test before itself is performed. Although the address is discriminated, in the third modification, the fire detector 20 that performs the test two times before the self transmits the test result signal as in the present embodiment, and then the first predetermined When the fire detector 20 that performs the previous test does not transmit a test result signal even after a lapse of time, the test of its own infrared sensor 23 is executed.

  Each of the fire detectors 20 in the modified example 3 is the address of the fire detector 20 that executes the test one before the self among the fire detectors 20 connected to the transmission line L1 (or L2). Address) and the storage unit 24 (an example of the previous address storage means and the test order storage means) in which the order of executing the tests of each fire detector 20 is stored, and the address of executing the test two times before the self The fire which owns the address for executing the test one before the first time even after the first predetermined time has elapsed since the transmission / reception unit 25 received the test result signal transmitted from the fire detector 20 having When the transmission / reception unit 25 does not receive the test result signal transmitted from the sensor 20, the control unit 21 includes a test execution unit that executes a test of its own infrared sensor 23.

  In this case, the addresses of the fire detectors 20 on the transmission lines L1 and L2 may be serial numbers or may not be serial numbers. For example, when a test result signal transmitted from the fire detector 20 to be tested first on the transmission line L1 is received by the other fire detector 20 via the transmission line L1, the control of the other fire detector 20 is performed. The unit 21 refers to the storage unit 24 and executes the test if the test order is next.

  When each fire detector 20 performs a test according to the order, the control unit 21 of any of the fire detectors 20 owns the fire detector 20 having an address to be tested two times before its own address. Is transmitted from the fire detector 20 that owns the address to be tested one time before its own address even after the first predetermined time has elapsed since the transmission / reception unit 25 received the test result signal transmitted from When the transmission / reception unit 25 does not receive the test result signal, the test of its own infrared sensor 23 is executed.

  Thereby, in addition to the effect of the modification 1, even if the fire detector 20 to be tested one before the own fire detector 20 is removed, the test is continued without interruption. It can be carried out.

In the third modification, the storage unit 24 stores the address (previous address) of the fire detector 20 that executes the test one before the self, and each fire detector 20 on the same transmission line L1, L2. However, only the order in which the tests of the fire detectors 20 are executed on the same transmission line L1, L2 may be stored. The first predetermined time can be measured.
Moreover, in the modified examples 1 to 3, the test order storage unit of the fire receiver 10 is configured so that each fire detector 20 is provided for each transmission line L1 and L2 in accordance with the test order set in each fire detector 20. The test order is stored in correspondence with the addresses. Then, the fire receiver 10 transmits a test result return command to each fire detector 20 periodically, for example, every week using this test order storage unit, and the test result is returned as a response. Receive a signal.

  In the above-described embodiment and the first to third modifications, the fire receiver 10 individually transmits test result return commands specifying addresses to all the fire detectors 20 on the transmission lines L1 and L2. As described above, a test result return command specifying an address may be transmitted only to the fire detector 20 that performs the test first on the transmission lines L1 and L2. When the fire detector 20 that performs the test first responds and transmits the test result signal, the fire detector 20 that performs the second test that receives the test result signal performs the test and transmits the test result signal. After that, the third,..., And last fire detectors 20 to be tested operate in the same manner, and the fire receiver 10 receives test result signals from all the fire detectors 20 on the transmission lines L1 and L2. May be received.

Moreover, in the said embodiment and the modification 1 thru | or 3, the fire detector 20 which tests first on the transmission lines L1 and L2 shall perform test operation | movement, if 2nd predetermined time passes. The test operation may be performed when a test start command transmitted from the fire receiver 10 is received. That is, the fire receiver 10 sends the test result return command to the fire detector 20, for example, 10 seconds before the test result return command is sent to the fire detector 20. Send a test start command. Even in that case, it is possible to prevent the test timing from overlapping with other fire detectors 20.
At this time, the fire detector 20 that performs the second test from the beginning on the transmission lines L1 and L2 is the test result that the fire detector 20 that performs the test first even after the first predetermined time has elapsed from the test start command. If the signal is not transmitted, the self test may be started.

  In the embodiment and any one of the first to third modifications, the fire detector 20 is one before the self among the fire detectors 20 connected on the same transmission lines L1 and L2. The test result signal transmitted from the fire detector 20 that executes the test has been described as executing the test of its own fire detection unit. Instead, it is connected to the same transmission lines L1 and L2. When a test result return command transmitted to the fire detector 20 that executes the test one before the self is received, the test of the fire detection unit of the self is performed. Also good. Even in this case, it is possible to prevent the test timing from overlapping with other fire detectors 20.

  In any of the above-described embodiments and Modifications 1 to 3, the fire detector 20 has a test result signal transmitted from the fire detector 20 having an address for executing the test two times before the self. If the test result signal transmitted from the fire detector 20 having the address for executing the test one time before the self is not received even after the first predetermined time has passed, Although it has been described that the test of the detection unit is executed, instead of receiving the test result return command transmitted to the fire detector 20 having the address for executing the test one time before the self, If the test result signal is not received from the fire detector 20 having the address for executing the test one time before the self even after the third predetermined time has elapsed, the test of the fire detection unit of the self is executed. You can do it . In consideration of various commands and signal transmission errors, the third predetermined time may be set to about 3 seconds, for example.

Moreover, you may implement the said embodiment and the modifications 1 thru | or 3 suitably combining.
In the present invention described above, the fire detector 20 is transmitted from the fire detector 20 that executes the test N times before itself among the fire detectors 20 connected on the same transmission lines L1 and L2. When the test result signal to be received is received, or among the fire detectors 20 connected on the same transmission lines L1 and L2, the test result signal is transmitted to the fire detector 20 that executes the test N times before itself. When the test result return command is received, the test of its own fire detection unit may be executed, and as described in the embodiment and the first to third modifications, the number is not limited to N = 1.
At this time, the fire detector 20 that performs the test up to the Nth time on the transmission lines L1 and L2 performs the (M + 1) -Nth test as the fire detector 20 that executes the test N times before the self. A fire detector 20 may be used. Here, M is the connectable number or the total number (number) of the fire detectors 20 connected on the same transmission lines L1 and L2. Even in this case, it is possible to prevent the test timing from overlapping with other fire detectors 20. Note that the fire detector 20 that performs the test up to the Nth time on the transmission lines L1 and L2 transmits the current test result to the fire receiver 10 at the next test result return timing.

  In the embodiment, the fire detector is described as a flame detector. However, it goes without saying that the present invention can be applied to other fire detectors such as a smoke detector and a heat detector.

  DESCRIPTION OF SYMBOLS 10 Fire receiver, 11 Control part, 12 Display operation part, 13 Storage part, 14 Transmission / reception part, 20 Fire detector, 21 Control part, 22 Test light source, 23 Infrared sensor, 24 Storage part, 25 Transmission / reception part, 26 Timer, L1, L2 Transmission line.

Claims (5)

A plurality of fire detectors with a test function are connected to the transmission line from the fire receiver, the fire receiver transmits a test result return command to each fire detector via the transmission line, In response to the test result return command, in a fire alarm facility that transmits a test result signal to the fire receiver via the transmission line,
The fire detector is
Address storage means for storing its own address uniquely set in each fire detector;
A receiving means for receiving a test result return command from the fire receiver or a test result signal from another fire detector via a transmission line;
A test execution means for executing a test of the fire detection unit;
With
The test execution means includes
When the receiving means receives a test result signal transmitted from a fire detector having an address before its own address, or to a fire detector having an address before its own address When the receiving means receives the test result return command transmitted to the device, it executes the test of its own fire detection unit,
Even if a first predetermined time elapses after the reception means receives the test result signal transmitted from the fire detector having the address two before the own address, one more than the own address. If the receiving means does not receive the test result signal transmitted from the fire detector that owns the previous address, the test of its own fire detection unit is executed.
Or, even if the third predetermined time has elapsed after the receiving means has received the test result return command transmitted to the fire detector that owns the address immediately before its own address, A fire alarm system characterized in that when the receiving means does not receive a test result signal transmitted from a fire detector having an address one before the address, the test of its own fire detection unit is executed . A plurality of fire detectors with a test function are connected to the transmission line from the fire receiver, the fire receiver transmits a test result return command to each fire detector via the transmission line, In response to the test result return command, in a fire alarm facility that transmits a test result signal to the fire receiver via the transmission line,
The fire detector is
Address storage means for storing its own address uniquely set in each fire detector;
A receiving means for receiving a test result return command from the fire receiver or a test result signal from another fire detector via a transmission line;
A test execution means for executing a test of the fire detection unit;
With
The test execution means receives the test result signal transmitted from the fire detector having the address one before the own address, or receives the address one previous from the own address. When the receiving means receives the test result return command transmitted to the fire detector that it owns, it executes the test of its own fire detection unit ,
The fire detector with the smallest address is
When the second predetermined time longer than the cycle of one cycle in which all the fire detectors execute the test passes after the test is executed, the test of the fire detection unit of itself is executed. fire alarm system. A plurality of fire detectors with a test function are connected to the transmission line from the fire receiver, the fire receiver transmits a test result return command to each fire detector via the transmission line, In response to the test result return command, in a fire alarm facility that transmits a test result signal to the fire receiver via the transmission line,
The fire detector is
Address storage means for storing its own address uniquely set in each fire detector;
A receiving means for receiving a test result return command from the fire receiver or a test result signal from another fire detector via a transmission line;
A test execution means for executing a test of the fire detection unit;
Pre-address storage means for storing an address of a fire detector that executes a test before one of the fire detectors connected to the transmission line;
Test order storage means for storing the order in which tests of fire detectors connected to the transmission line are performed;
The receiving means receives the state response signal transmitted in response to the state collection command from the fire receiver, thereby grasping the installation state of the fire detector connected to the transmission line, and storing the test order. Referring to the means, the address of the fire detector that executes the test one time before the self is recognized, and when the recognized address is different from the address of the fire detector stored in the previous address storage means, Address updating means for updating the address as a fire detector address stored in the previous address storage means;
With
The test execution means receives the test result signal transmitted from the fire detector having the address stored in the previous address storage means, or is stored in the previous address storage means. When the receiving means receives the test result return command transmitted to the fire detector having the address, it executes the test of its own fire detection unit.
Fire alarm equipment characterized by that. A plurality of fire detectors with a test function are connected to the transmission line from the fire receiver, the fire receiver transmits a test result return command to each fire detector via the transmission line, In response to the test result return command, in a fire alarm facility that transmits a test result signal to the fire receiver via the transmission line,
The fire detector is
Address storage means for storing its own address uniquely set in each fire detector;
A receiving means for receiving a test result return command from the fire receiver or a test result signal from another fire detector via a transmission line;
A test execution means for executing a test of the fire detection unit;
Pre-address storage means for storing an address of a fire detector that executes a test before one of the fire detectors connected to the transmission line;
With
The test execution means includes
When the receiving means receives the test result signal transmitted from the fire detector having the address stored in the previous address storage means, or the fire detection having the address stored in the previous address storage means When the receiving means receives the test result return command transmitted to the container, it executes the test of its own fire detection unit,
Even if the first predetermined time elapses after the reception means receives the test result signal transmitted from the fire detector having the address to execute the test two times before the self, one more than the self If the receiving means does not receive the test result signal transmitted from the fire detector having the address to perform the test before, the test of its own fire detection unit is executed.
Alternatively, even if a third predetermined time has elapsed since the receiving means received the test result return command transmitted to the fire detector having the address for executing the test before itself, A fire characterized in that if the receiving means does not receive a test result signal transmitted from a fire detector having an address for executing a test before itself, the fire detection unit is tested. Notification equipment. In response to a test result return command that is connected to a transmission line from a fire receiver and is received from the fire receiver via the transmission line, a test result signal is transmitted to the fire receiver via the transmission line. In the fire detector that
Address storage means for storing its own address uniquely set in each fire detector;
A receiving means for receiving a test result return command from the fire receiver or a test result signal from another fire detector via a transmission line;
When the receiving means receives a test result signal transmitted from a fire detector having an address before its own address, or to a fire detector having an address before its own address When the receiving means receives the test result return command transmitted to the device, it executes the test of its own fire detection unit,
Even if a first predetermined time elapses after the reception means receives the test result signal transmitted from the fire detector having the address two before the own address, one more than the own address. If the receiving means does not receive the test result signal transmitted from the fire detector that owns the previous address, it executes the test of its own fire detection unit.
Or, even if the third predetermined time has elapsed after the receiving means has received the test result return command transmitted to the fire detector that owns the address immediately before its own address, And a test execution means for executing a test of its own fire detection unit when the reception means does not receive a test result signal transmitted from a fire detector having an address before the address. Fire detector.

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